Correlating LHCb B_s^0 to \mu^+ \mu^- Results with the ATLAS-CMS Multijet Supersymmetry Search

TL;DR

This paper demonstrates that a specific supersymmetric model, No-Scale Flipped SU(5), aligns with recent LHCb B_s^0 to mu+ mu- decay results and evades current ATLAS-CMS multijet SUSY search limits, explaining small observed excesses.

Contribution

It shows that No-Scale Flipped SU(5) is consistent with recent experimental results and provides a benchmark model fitting multiple LHC observations.

Findings

The model predicts Br(B_s^0 to mu+ mu-) = 3.5 x 10^-9, within experimental bounds.

The benchmark gaugino mass scale is M_{1/2} = 708 GeV.

The model's particle masses are consistent with current collider constraints.

Abstract

We show that the No-Scale Flipped SU(5) construction is transparently consistent with recent LHCb results for B_s^0 to \mu^+ \mu^- decays, due primarily to suppression from the rather small value of tan\beta ~ 20 that is globally enforced across the model space. This fact should be interpreted in conjunction with the demonstrated evasion of mass limits from the ATLAS and CMS SUSY searches and the more important potential explanation of small observed excesses in the multijet data. The No-Scale Flipped SU(5) benchmark model that best fits these excesses has a gaugino mass scale of M_{1/2} = 708 GeV, which drives masses for the bino-dominated LSP m_\chi_1^0 = 143.4 GeV, light stop m_t1 = 786 GeV, gluino m_g = 952 GeV, and heavy squark m_uL = 1490 GeV. The corresponding total prediction for the rare B-decay of Br(B_s^0 to \mu^+ \mu^-) = 3.5 x 10^-9 suggests that the SUSY contribution may indeed be much smaller than that expected from the Standard Model in this framework, fitting quite comfortably within the very tightly constrained region remaining viable after the most recent LHCb measurements.